KR20090089060A - Method for processing vedeo signal ouputted as picture in picture display and broadcasting receiver enabling of the method - Google Patents

Abstract

A method for processing an image of a broadcasting receiver realizing a pip screen and the broadcasting receiver using the method are provided to remove afterimages of image signals outputted from a main screen and a PIP screen, thereby realizing optimum image quality. PIP(Picture In Picture) screen output is selected from a user(S201). Source information of image signals outputted to a PIP screen and a main screen is determined(S202). A location and a size of the main screen and the PIP screen are determined(S203). A motion rate of image signal inputted to the main screen and the PIP screen is measured by using the location and size information(S204). The image signal is outputted at 120 Hz.

Description

TECHNICAL FOR PROCESSING VEDEO SIGNAL OUPUTTED AS PICTURE IN PICTURE DISPLAY AND BROADCASTING RECEIVER ENABLING OF THE METHOD}

According to the present invention, a broadcast receiver employing an image processing method and a broadcast receiver employing the method can perform a motion compensation by applying a frame rate conversion (FRC) function even when a PIP screen is implemented in a broadcast receiver implementing 120Hz technology. It is about.

Today, with the development of the image technology, development of a broadcast receiver employing the 120 Hz technology for realizing an image signal in a frame of 120 Hz has been in full swing as a technique for improving the problems caused by the afterimage of the LCD panel.

The 120Hz technology is a technology that generates a virtual frame between frames of a 60Hz video signal, and then converts the generated virtual frame into a 120Hz video signal by sandwiching the generated virtual frame. For example, after generating the frame 1.5 with reference to the frame 1 and the frame 2, the image signal of 120 Hz may be generated by sandwiching the frame 1.5 between the frame 1 and the frame 2.

However, when a video signal is input, a broadcast receiver according to the related art measures a motion rate of a video signal with reference to an existing frame, generates a virtual frame, and performs motion compensation (ie, motion compensation). The Frame Rate Conversion (FRC) function, which performs MEMC (Motion Estimation Motion Compensation), is used.When outputting simultaneous screens such as PIP screens, it is difficult to judge motions. Therefore, the FRC function cannot be used for the main screen or PIP screen. There was a problem.

1 is a diagram illustrating an embodiment of a PIP screen output from a broadcast receiver of the prior art. Referring to FIG. 1, the broadcast receiver of the prior art may output an image signal to the A region 101 and the B region 102, respectively.

However, since the conventional broadcast receiver performs the RCE function on the entire area without distinguishing between the A area 101 and the B area 102, the motion rate measured near the boundary between the A area 101 and the B area 102. And there is a problem that an error (for example, lumping or crushing of the image) occurs on the screen due to the motion compensation accordingly.

Therefore, when the broadcast receiver of the prior art implements a PIP screen, the FRC function has to be turned off, and thus there is a problem that motion compensation cannot be performed on the video signal.

Accordingly, there is an urgent need to develop a broadcast receiver capable of performing motion compensation by applying an FRC function even when a PIP screen is implemented in a broadcast receiver implementing 120Hz technology by solving the problems of the prior art.

Accordingly, an object of the present invention is to provide a broadcast receiver capable of performing motion compensation by applying an FRC function even when a PIP screen is implemented in a broadcast receiver implementing 120Hz technology.

In accordance with another aspect of the present invention, there is provided a method of processing a video signal of a broadcast receiver; Determining source information of an image signal output to a main screen and a PIP screen, respectively; Determining a position and a size of each of the main screen and the PIP screen; Measuring a motion rate of the video signal input to each of the main screen and the PIP screen using the determined position and size information; And performing motion compensation of the video signal input to each of the main screen and the PIP screen by using the determined source information and the measured motion rate, and outputting the video signal at 120 Hz. do.

In addition, the broadcast receiver according to another embodiment of the present invention comprises a user interface for receiving a selection input PIP screen output from the user; Determine source information of an image signal output to the main screen and the PIP screen, determine the position and size of each of the main screen and the PIP screen, and use the determined position and size information to determine the main screen and the PIP. A scaler for measuring a motion rate of the video signal input to each screen; After performing the motion compensation of the video signal input to each of the main screen and the PIP screen by using the determined source information and the measured motion rate FRC module for outputting the video signal at 120 Hz Include.

According to the present invention, even when the user selects the PIP screen output from the broadcast receiver, the video signal output to the main screen and the PIP screen by performing motion compensation by applying the FRC function to the video signals output to the main screen and the PIP screen, respectively Eliminates the afterimage of the image to achieve the best image quality.

Hereinafter, a method of processing a video signal in a broadcast receiver and a broadcast receiver employing the method will be described in detail with reference to the accompanying drawings.

2 is a flowchart illustrating a process of processing a video signal in a broadcast receiver according to an embodiment of the present invention.

Referring to FIG. 2, the broadcast receiver of the present invention receives a PIP (Picture In Picture) screen output from the user in step S201. The PIP screen output is a function of simultaneously outputting a video signal output from the broadcast receiver to the main screen and the PIP screen (or sub-screen), and the user may select the PIP screen output in a predetermined user interface.

The user may designate a source of an image signal output to the main screen and the PIP screen, respectively. For example, the user may designate a broadcast signal received on channel '11' as the main screen and select 'RGB' as the PIP screen.

If the user selects the output of the PIP screen, in step S201, the broadcast receiver of the present invention determines the source information of the video signal output to the main screen and the PIP screen, respectively. For example, the source information of the video signal may be classified into an RGB input, a broadcast signal, a component input, and the like, and whether or not to apply the FRC function may vary according to the source information.

In step S202, the broadcast receiver of the present invention determines the position and size of each of the main screen and the PIP screen. Location and size information of the main screen and the PIP screen may be a default value in the internal memory, or may be a value input if the user selects and inputs the location and size of the main screen and the PIP screen.

In step S203, the broadcast receiver measures the motion rate of the video signal input to each of the main screen and the PIP screen by using the determined position and size information. In this case, the broadcast receiver may measure a motion rate by applying a mask to each of the main screen and the PIP screen using location and size information of the main screen and the PIP screen.

3 is a diagram illustrating an embodiment of a mask applied to each of a main screen and a PIP screen according to the present invention. Referring to FIG. 3, the broadcast receiver of the present invention may apply a mask 301 applied to a main screen and a mask 302 applied to a PIP screen.

The broadcast receiver measures the motion rate by comparing the previous frame and the current frame of the video signal output on the main screen, and measures the motion rate by comparing the previous frame and the current frame of the video signal output on the PIP screen. For example, the motion rate may be measured by measuring and comparing vector points of the previous frame and the current frame.

In operation S205, the broadcast receiver performs motion compensation on the video signal input to each of the main screen and the PIP screen by using the determined source information and the measured motion rate.

4 is a diagram illustrating a result of performing motion compensation on each of the image signals outputted from the main screen and the PIP screen according to an embodiment of the present invention. Referring to FIG. 4, the broadcast receiver according to the present invention performs motion compensation on each of an image signal output to the main screen region 401 and an image signal output to the PIP screen region 402, and then outputs the resulting image. can do.

Motion compensation may be performed by generating and embedding a virtual frame into an image signal of 60 frames, thereby generating an image signal of 120 frames. At this time, the number of new virtual frames to be changed depends on the measured motion rate.

Therefore, in the present invention, even when the user selects the PIP screen output from the broadcast receiver, the motion compensation is performed by applying the FRC function to the video signals output to the main screen and the PIP screen, respectively, so that the output is displayed on the main screen and the PIP screen. Eliminating the afterimage of the video signal has the effect of achieving the optimum image quality.

Further, according to an embodiment, the broadcast receiver may determine whether to perform the motion compensation of the video signal output to each of the main screen or the PIP screen according to the determined source information. For example, a broadcast signal is output to the main screen. When the RGB input is output to the PIP screen, the broadcast receiver may determine to perform motion compensation on the broadcast signal output on the main screen and not perform motion compensation on the RGB input output on the PIP screen.

In addition, according to an embodiment, the broadcast receiver receives a selection input from the user on whether to perform motion compensation on the main screen or the PIP screen, and the video inputted on each of the main screen or the PIP screen depending on whether the selected motion compensation is performed. It is possible to determine whether to perform motion compensation of the signal.

FIG. 5 is a diagram illustrating an embodiment of a user interface that allows a user to select whether to perform motion compensation on each of a main screen or a PIP screen according to the present invention. Referring to FIG. 5, a user may select whether to perform motion compensation of a main screen or a PIP screen, and may select a level (eg, high or low) at which motion compensation is performed. The level at which motion compensation is performed refers to the degree of the motion rate referenced when generating the virtual frame. As the level increases, the degree of motion rate referred to becomes higher, so that a more natural image can be output.

When the user selects a level at which motion compensation is performed, the broadcast receiver may perform the motion compensation of the video signal input to each of the main screen or the PIP screen at the input level. For example, the user may select high motion compensation of the main screen, low motion compensation of the PIP screen, or off.

6 is a block diagram illustrating a configuration of a broadcast receiver for processing a video signal according to an embodiment of the present invention. Referring to FIG. 6, a broadcast receiver for processing a video signal according to the present invention may include a user interface 601, a scaler 602, and an FRC module 603, and according to an embodiment, the receiver 604 and the panel. 605 may include.

The user interface 601 selects and inputs a PIP screen output from a user.

The scaler 602 determines source information of an image signal output to the main screen and the PIP screen, determines the position and size of each of the main screen and the PIP screen, and uses the determined position and size information. After measuring the motion rate of the video signal input to each of the main screen and the PIP screen, the input video signal is output to the FRC module 603. In this case, the scaler 604 may output an image signal in RGB 24 bits.

The FRC module 603 performs motion compensation of the video signal input to each of the main screen and the PIP screen using the determined source information and the measured motion rate, and then converts the video signal to the 120 Hz. Output At this time, the FRC module 603 measures the motion rate of the video signal input to each of the main screen and the PIP screen once more, calculates an average value with the value measured by the scaler 602, and then calculates an average value. By using for motion compensation, a more accurate motion rate can be used.

The FRC module may determine whether to perform the motion compensation of an image signal output to each of the main screen or the PIP screen according to the determined source information.

The user interface may receive a selection input from the user to determine whether to perform motion compensation of the main screen or the PIP screen, and the FRC module may be applied to each of the main screen or the PIP screen according to whether the selected motion compensation is performed. It is possible to determine whether to perform motion compensation on the input image signal.

According to an embodiment, the user interface receives a level of motion compensation applied to the main screen or the PIP screen from the user, and the FRC module inputs each of the main screen or the PIP screen to the received level. The motion compensation of the video signal may be performed.

The receiver 604 outputs an image signal output from the FRC module 603 to the panel 605.

The broadcast receiver according to the present invention has been described so far, and the technical details described in the above embodiments may be applied to the broadcast receiver of FIG. 6, and thus the detailed description thereof will be omitted below.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above-described embodiments, which can be variously modified and modified by those skilled in the art to which the present invention pertains. Modifications are possible. Accordingly, the spirit of the present invention should be understood only by the claims set forth below, and all equivalent or equivalent modifications thereof will belong to the scope of the present invention.

1 is a view showing an embodiment of a PIP screen output from the broadcast receiver of the prior art.

2 is a flowchart illustrating a process of processing a video signal in a broadcast receiver according to an embodiment of the present invention.

3 is a diagram illustrating an embodiment of a mask applied to each of a main screen and a PIP screen according to the present invention;

4 is a diagram illustrating a result of performing motion compensation on each of image signals outputted from a main screen and a PIP screen according to an embodiment of the present invention;

FIG. 5 illustrates an embodiment of a user interface that allows a user to select whether to perform motion compensation for each of the main screen or PIP screen according to the present invention.

6 is a block diagram showing a configuration of a broadcast receiver for processing a video signal according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

601: user interface

602 scaler

603: FRC module

Claims (8)

In the video signal processing method of the broadcast receiver, Selecting and receiving a PIP (Picture In Picture) screen output from a user; Determining source information of an image signal output to a main screen and a PIP screen, respectively; Determining a position and a size of each of the main screen and the PIP screen; Measuring a motion rate of the video signal input to each of the main screen and the PIP screen using the determined position and size information; And Performing motion compensation on the video signal input to each of the main screen and the PIP screen using the determined source information and the measured motion rate, and then outputting the video signal at 120 Hz Image signal processing method of a broadcast receiver comprising a. The method of claim 1, Performing motion compensation of an image signal output to each of the main screen and the PIP screen by using the determined source information and the measured motion rate, Determining whether to perform the motion compensation of an image signal output to each of the main screen or the PIP screen according to the determined source information Image signal processing method of a broadcast receiver comprising a. The method of claim 1, Receiving a selection input from the user to perform motion compensation on the main screen or the PIP screen; More, Performing motion compensation of the video signal input to each of the main screen and the PIP screen by using the determined source information and the measured motion rate, Determining whether to perform motion compensation of the video signal input to each of the main screen or the PIP screen according to whether the selected motion compensation is performed; The video signal processing method of the broadcast receiver further comprising. The method of claim 1, Receiving a level of a motion compensation applied to the main screen or the PIP screen from the user More, Performing motion compensation of an image signal input to each of the main screen and the PIP screen by using the determined source information and the measured motion rate And performing the motion compensation of the video signal input to each of the main screen or the PIP screen at the input level. In a broadcast receiver, A user interface for receiving an input of a PIP screen output from a user; Determine source information of an image signal output to the main screen and the PIP screen, determine the position and size of each of the main screen and the PIP screen, and use the determined position and size information to determine the main screen and the PIP. A scaler for measuring a motion rate of the video signal input to each screen; Frame rate conversion for outputting the video signal at 120 Hz after performing motion compensation on the video signal input to each of the main screen and the PIP screen using the determined source information and the measured motion rate. ) module Broadcast receiver comprising a. The method of claim 5, The FRC module, And determining whether to perform the motion compensation of the video signal output to each of the main screen or the PIP screen according to the determined source information. The method of claim 5, The user interface receives a selection input from the user whether to perform the motion compensation of the main screen or the PIP screen, The FRC module, And determining whether to perform motion compensation of the video signal input to each of the main screen or the PIP screen according to whether the selected motion compensation is performed. The method of claim 5, The user interface receives a level of motion compensation applied to the main screen or the PIP screen from the user, The FRC module, And performing the motion compensation of the video signal input to each of the main screen or the PIP screen at the input level.

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